I am trying to think of an algorithm to implement this for a given n bit binary number. I tried out many examples but am unable to find out any pattern . So how shall I proceed ?
How about this:
Convert the number to base 4 (this is trivial by simply combining pairs of bits). 5 in base 4 is 11. The values base 4 that are divisible by 11 are somewhat familiar: 11, 22, 33, 110, 121, 132, 203, ...
The rule for divisibility by 11 is that you add all the odd digits and all the even digits and subtract one from the other. If the result is divisible by 11 (which remember is 5), then it's divisible by 11 (which remember is 5).
Or another one:
This should have a fairly efficient HW implementation because it's mostly bit-slicing, followed by N/2 adders, where N is the number of bits in the number you're interested in.
Note that after adding the digits and subtracting, the maximum value is 3/4 * N, so if you have 16-bit numbers max, you can get at most 12 as a result, so you only need to check for 0, ±5 and ±10 explicitly. If you're using 32-bit numbers then you can get at most 24 as a result, so you need to also check if the result is ±15 or ±20.
Make a Deterministic Finite Automaton (DFA) to implement the divisibility check and implement the DFA in hardware.
Creating a DFA for divisibility by 5 is easy. You just need to notice the remainders and check what 2r (mod 5) and 2r + 1(mod 5) map to. There are many websites that discuss this. For example this one.
There are well-known examples to convert DFA to a hardware representation as well.
Well , I just figured out ... number mod 5 = a0 * 2^0 mod 5 + a1 * 2^1 mod 5 +a2* 2^2 mod 5 + a3 * 2^3 mod 5 + a4 * 2^4 mod 5 + .... = a0 (1) + a1(2) +a2 (-1) +a3 (-2) +a4 (1) repeats ...
Hence difference of odd digits + 2 times difference of even digits = divisible by 5
for example ... consider 110010
difference of odd digits + 2 times difference of even digits = 01 + 2*(10)=01 + 100 = 101 is divisible by 5 .